Poa annua: An annual species?

As the Latin name annua implies, the species Poa annua L. is thought to have an annual life cycle. Yet, there are many reports in literature of P. annua persisting as a perennial. Considering that P. annua senescence patterns do not align with other true annual species, we hypothesized that P. annua is similar to other perennial, C3 turfgrass species that are subject to a confluence of environmental factors that can cause mortality. Four experiments were conducted in Knoxville, TN with the objective of determining environmental factors lethal to P. annua. A field monitoring study assessed 100 P. annua plants across ten grassland micro-environments from May to October 2020. Forty plants survived the summer and confirmed the existence of perennial P. annua ecotypes. Analysis of environmental factors at the time of plant death indicated soil moisture, soil temperature, and pathogenic infection were associated with mortality. A series of glasshouse or field experiments were conducted to investigate the effects of each factor on P. annua mortality. Soil moisture and soil temperature were not lethal to P. annua in the glasshouse, except under extreme conditions not typical in the field. A field study assessed mortality of plants from pathogenic infection and indicated that P. annua plants treated with fungicide throughout the summer survived year-round, whereas plants not receiving fungicide applications senesced. These findings support our hypothesis that P. annua is of a perennial life cycle, which can be influenced by environmental conditions. We suggest that the name P. annua is likely a misnomer based on its modern interpretation.


Introduction
Poa annua L. is a C 3 grass species and a common component of urban grasslands. The ubiquity of P. annua in terms of both distribution and abundance has been compared to that of Homo sapiens [1]. Although the species can be desirable, it is also recognized as the most troublesome weed of urban grasslands and second most troublesome weed of all grass crops [2].
An annual species is defined by abrupt senescence following completion of a single reproductive cycle, even if growing conditions are optimal [3]. Grass crops such as Triticum spp.
(wheat) and Zea mays L. (maize) are annuals that senesce after fruiting regardless of environmental surroundings [4,5]. Despite its name meaning annual in Latin, P. annua does not Although the nature of P. annua transience in some situations remains uncertain, review of literature indicates the species may be incorrectly botanically characterized [60]. If any environmental factors are causing plant death rather than programmed senescence after inflorescence production, classification as an annual species does not follow the accepted definition of such a life cycle [3]. Given the world-wide presence of the species and difficulties related to management [2,61], efforts to better understand P. annua life cycle are warranted. Therefore, the objective of this study was to determine environmental factors lethal to P. annua.

Ethics statement
Field research and sample harvesting was conducted on university property, Three Ridges Golf Course, or Oak Ridge Country Club. No permits were required for testing or plant collection. Permission for use was granted by site managers.

Life cycle observation
An observational field study was initiated on 11 May 2020 at three locations in Knoxville, TN (S1 Table). One hundred P. annua plants were monitored throughout the summer and fall until 27 Oct. 2020. Monitoring occurred in ten unique micro-environments across the three study locations (Table 1). Experimental areas within micro-environments measured 1 x 2 m. Ten P. annua plants were identified based on their similar size and growth stage and monitored within each area. Metal rings (7.6 cm in diameter and 2.8 cm in length) were installed around each plant to allow observation of the same P. annua plants throughout the study. Herbicides were not applied to the experimental areas during the observational period.
At study initiation and every three weeks thereafter, photographs were taken of each P. annua plant. Plant mortality was also visually recorded on each rating date and scored as a lack of green tissue aboveground within each metal ring. A multifactor F-score analysis of climatic data related to death events was conducted using Python (Version 3.9.9, https://www. python.org/) programming language. Libraries used in analyses included 'pandas' (v. 1

Soil temperature evaluation
A glasshouse experiment was conducted from 24 Feb to 14 April 2021 in Knoxville, TN (35.946590, -83.939360) to determine the effects of soil temperature on P. annua mortality. Two experimental runs were conducted concurrently in adjacent glasshouse bays. Ecotypes from micro-environments one and two (Table 1) in the aforementioned observational study were selected for inclusion on the basis of observed length. Mature P. annua plants were harvested from the field on 24 Feb. 2021. Harvest location one was comprised of plants that senesced during 2020, whereas harvest location two contained plants that survived the entire duration of our observational experiment in 2020. Plants were harvested within a 7.5 m 2 area as undisturbed soil cores (10.2 cm diameter) containing aboveground biomass and an intact root system. Plants of similar size, tiller number, and growth stage (e.g., no inflorescence) were selected for collection. Extracted soil cores were cut to a uniform depth of 7.6 cm, such that no roots were visibly protruding.
Experimental setup and design. Soil cores containing plants were immediately transferred to a glasshouse and installed in water baths devoid of water at the time of installation. Water baths were constructed in advance of plant harvest by mounting polyvinyl chloride (PVC) pipes (10.2 cm in length and diameter) in plastic containers (51 x 39 x 15 cm) (Fig 1). Pipes were affixed to the container using waterproof caulk atop drainage holes. Three P. annua plants of each ecotype were installed in pipes by sliding the core into the pipe without disturbance. Pipes were randomized within each water bath. Filter paper was placed in the bottom of each tube to prevent loss of soil while allowing for water movement.
Once installed in water baths, plants were supplied with complete fertilizer (20N-20P 2 O 5 -20K 2 O; Southern Ag Triple Twenty with minors; Hendersonville, NC) to deliver 49 kg N ha -1 and immediately irrigated (5 mm) via an overhead sprinkler system.
Plants were acclimated in water bath systems under glasshouse conditions for seven days (24 Feb to 3 March 2021) before treatments were imposed. During this period, glasshouse conditions averaged 50% relative humidity and 22.8˚C air temperature. A 16/8 hour day/night artificial photoperiod was imposed via metal halide lights (1000 W; P.L Light Products, Beamsville, ON, Canada) with night occurring from 2200 to 0600 hours. Five mm of irrigation was applied daily between 0700 and 0900 hours. Plants were clipped to a height of 2.5 cm by hand using scissors on days three and seven (final) of acclimation.
After seven days of acclimation, plants were subjected to one of four soil temperatures imposed by water baths for four weeks (3 to 31 March 2021). The method of using water baths to impose variable soil temperatures is similar to those used in other experiments investigating soil temperature effects on grass mortality [62,63]. Water baths were arranged in a split-plot design with three replications. The whole plot factor was soil temperature whereas the splitplot factor was P. annua ecotype (n = 72 plants; 2 ecotypes x 3 plant replications x 4 soil temperatures x 3 water bath replications).
Aquarium heaters with digital thermometers (500 W; Hygger, Renton, WA) were used to manipulate water temperature in each bath to augment soil temperature. Each water bath was also equipped with a 4 W circulation pump to prevent algal infestation and a secondary liquid thermometer to monitor water temperature. Heat from water in baths was transferred to soil cores containing P. annua until soil temperature was in equilibrium with water temperature.
For the duration of this experiment, water bath temperatures were 21.1, 26.7, 32.2, or 37.8˚C. Temperatures in this range were chosen because previous studies assessing soil temperature effects on C 3 grasses (such as P. annua) consider 20˚C and 35˚C to be optimal and supraoptimal soil temperatures, respectively, for root growth [62,63]. For water baths set to 26.7, 32.2, or 37.8˚C, water was added outside of PVC pipes containing P. annua plants to a depth of 7.6 cm. Water baths set to these temperatures were placed on a heating mat (iPower, Irwindale, CA) to prevent heat loss and ensure intended temperatures were achieved. At treatment initiation, aquarium heaters were set to the desired temperature. Within 12 hours of heat imposition, soil temperatures were in equilibrium with the desired water temperature. The 21.1˚C temperature was achieved using the same equipment devoid of water.
Soil temperatures were monitored in soil cores within one temperature replication of each water bath using external soil sensors (#3667; Spectrum Technologies Inc., Aurora, IL) programmed to record soil temperature every 15 min and transmitted to a micro station (Watch-Dog 1000 Series; Spectrum Technologies Inc., Aurora, IL). Micro stations also recorded air temperature and humidity every 15 minutes. Secondary digital soil thermometers (#6300; Spectrum Technologies Inc., Aurora, IL) were monitored daily in one replication of each water bath as well. In experimental run one, mean air temperature was 22.6˚C and mean relative humidity was 49.4%. In experimental run two, mean air temperature was 22.5˚C and mean relative humidity was 46.0%.
Soil temperature treatments were imposed for four weeks. During the treatment period, plants were clipped daily to a height of 2.5 cm by hand using scissors and water baths were refilled to the appropriate water level as needed. Plants were maintained at a constant gravimetric moisture content via addition of supplemental water (15 to 23 mL) twice per week. After four weeks of exposure to soil temperature treatments, plants were subjected to ambient soil temperature for two weeks (31 March to 14 April 2021) to assess the potential for regrowth. During this time, plants were not clipped, and supplemental irrigation (5 mm) was applied daily via an overhead misting system.
Data collection and analysis. Plants were visually evaluated daily for mortality, rated as all aboveground tissue necrotic, with death confirmed via assessments of photochemical efficiency using a handheld fluorometer (Fv/Fm meter; Opti-Sciences, Inc., Hudson, NH) to measure Fv/Fm ratio. Two readings were taken from each plant once per week after randomly placing five-to-ten attached leaves into dark adaption chambers for 20 minutes. Plants were considered dead when the Fv/Fm ratio was zero. For most plant species, Fv/Fm ratios in the range of 0.79 to 0.84 are considered optimum, whereas lower values indicate plant stress [64,65].
Data were subjected to analysis of variance using the SAS (University Edition, SAS, Cary, NC) mixed procedure. Fixed effects included experimental run, soil temperature, and P. annua ecotype, while water bath (block) was considered a random effect. Therefore, experimental run, soil temperature, and P. annua ecotype interactions were tested. Analysis of variance revealed experimental run and P. annua ecotype were not significant factors for photochemical efficiency data. Figures were generated in Prism (Prism 9 for Mac, Graph-Pad software, La Jolla, CA).

Soil water evaluation
A glasshouse experiment was conducted from 21 April to 9 June 2021 in Knoxville, TN (35.946590, -83.939360) to explore the effects of soil moisture on P. annua mortality at different soil temperatures. Two experimental runs were conducted simultaneously in separate glasshouse bays.
Because no significant ecotype interaction was identified in the soil temperature evaluation experiment, P. annua plants for this experiment were harvested from a single location to limit the number of experimental variables. On 21 April 2021, mature P. annua plants were harvested from micro-environment two (Table 1), where plants survived the entire experiment in 2020. Harvest methods were identical to those previously described. All harvested plants were of similar size and had inflorescences present at the time of collection. The collection area was treated with cyazofamid (Segway; PBI Gordon Corporation, Shawnee, KS) at 1.1 kg ha -1 24 hours prior to harvest to prevent confounding effects of soil pathogens. Fungicide was immediately irrigated into the soil after application.
Experimental setup and design. After harvest, soil cores containing P. annua plants were immediately transferred to a glasshouse. Soil cores were tightly wrapped with polyethylene plastic (0.15 mm thick) to prevent water loss via evaporation. Poa annua foliage was carefully moved to protrude out of a 2.5 cm incision at the top of each core (Fig 2). Four drainage holes were created in the bottom of soil cores. Plastic wrapped soil cores were installed in PVC pipes (10.2 cm in length and diameter).
Once installed in PVC pipes, plants underwent 7 d of acclimation (21 to 28 April 2021) in a glasshouse under conditions described previously for photoperiod, nutrient application, irrigation, and clipping. Ambient conditions during acclimation averaged 64.9% relative humidity and 22.2˚C air temperature in experimental run one and 53.9% relative humidity and 22.1˚C air temperature in experimental run two.
At the termination of the acclimation period, soil cores were saturated to the point of water freely draining through drainage holes. Water was allowed to drain overnight, resulting in soil cores at pot capacity at the onset of treatment; an approach used by other researchers exploring effects of soil water stress on plants [66]. Thirty-six P. annua plants in each experimental run were subjected to a 2 x 2 factorial arrangement of soil temperature and irrigation regime for six weeks (28 April to 9 June 2021). During treatment, plants received no supplemental nutrients and were clipped daily to a 2.5 cm height using scissors.
Soil temperature was either ambient or elevated via a heating mat (iPower, Irwindale, CA). Irrigation treatments included well-watered (n = 12) or full drought (n = 24; Fig 3). Irrigation needs were determined by calculating daily plant transpiration [66]. Individual PVC pipes were weighed at 1200 to 1300 hours daily. Daily transpiration was calculated as the difference in weight of each pot on successive days. The well-watered plants were irrigated by hand daily to maintain a weight of no less than 50 g of their initial weight. A syringe was inserted through the incision at the top of the core to facilitate controlled watering. Plants subjected to full drought conditions received no supplemental irrigation throughout the entirety of the study.
Air temperature, relative humidity, and soil temperature were monitored as previously described. In experimental run one, soil temperature averaged 26.8˚C in cores subjected to ambient conditions and 34.6˚C in cores subjected to elevated soil temperature. Mean air temperature was 26.6˚C and mean relative humidity was 59.4%. In experimental run two, mean soil temperatures were 24.7˚C and 32.0˚C for cores subjected to ambient and elevated soil temperature, respectively. Mean air temperature was 25.7˚C and mean relative humidity was 56.1.%.
Data collection and analysis. Data collection and analyses were similar to those described in the soil temperature experiment. Plants were evaluated daily for mortality on a binary scale where 0 = alive (green tissue observed) and 1 = dead (all tissue necrotic). Mortality was confirmed via photochemical efficiency readings. Poa annua photochemical efficiency was evaluated three times per week by measuring chlorophyll fluorescence using a handheld fluorometer (Fv/Fm meter; Opti-Sciences, Inc., Hudson, NH). Two readings were taken from each plant after randomly placing five-to-ten attached leaves into dark adaption chambers for 20 minutes. Volumetric water content (VWC) of soil was recorded at approximately a 5.0 cm depth on the day of mortality, or for those that survived, at the conclusion of the study by inserting a soil moisture sensor (ML3 ThetaProbe; Delta -T Devices, Cambridge, UK) into the center of each core and recording a single reading.
Visually rated mortality data were subjected to life cycle analysis in Prism (Prism 9 for Mac, Graph-Pad software, La Jolla, CA) using the Kaplan-Meier estimate of survival probabilities log rank test with P < 0.0001 determining differences in mortality.

Disease susceptibility evaluation
A field experiment was conducted at the East Tennessee AgResearch and Education Center (Knoxville, TN) from 27 May to 28 October 2021 to assess the impacts of fungicide application on P. annua mortality. The experimental site was a mixed stand of P. annua and zoysiagrass (Zoysia matrella Merr. cv. Trinity) atop a Sequatchie silt loam soil with a pH of 6.2 and 2.9% organic matter. The area was mown twice per week at a 1.3 cm height of cut and watered four times per week via automatic irrigation. Slow-release fertilizer (Gal-Xe ONE1 ; Simplot, Boise, ID) was applied to the entire area on 22 April 2021 to deliver 195 kg N ha -1 yr -1 . On 25 May 2021, the experimental area was treated with quinclorac (Drive XLR8; BASF Corporation, Research Triangle Park, NC) at 0.84 kg ha -1 + methylated seed oil (0.5% v/v) to control summer annual weeds.
The experiment was arranged as a randomized complete block design with 10 replications of two treatments applied to 1 m 2 plots. Treatments included either no fungicide application or fungicide mixtures including active ingredients from Fungicide Resistance Action Committee groups #2, 3, 5, 7, 11, and 21 intended to manage outbreaks of dollar spot, anthracnose, Pythium blight, and brown patch (S2 Table). Treatments were applied every 14 days from 26 May to 13 October 2021. Every two weeks, experimental units were visually assessed for P. annua mortality. An F-score analysis of climatic data associated with mortality was conducted using the same methods and packages as those used in the life cycle monitoring experiment.

Life cycle observation
In four of the 10 micro-environments (#2, #6, #7, and #9) all ten monitored P. annua plants survived the summer season, whereas in the other six micro-environments, all ten monitored plants senesced during the observational period. The ability of P. annua to survive year-round in certain environments in this study aligns with reports of perennial ecotypes .
Surviving plants exhibited a range of morphological characteristics. Plants from locations two and six were fine-textured, displayed lateral growth, and produced inflorescences periodically throughout summer (S1 Fig). Plants in locations seven and nine were coarse-textured with an upright growth habit and lacked inflorescences. Micro-environments conducive to P. annua survival were those where conditions were likely such that water was either not a limiting factor or where fungicides were applied. Analysis of environmental factors at the time of observed plant mortality corroborated these observations and indicated that sum precipitation, maximum soil temperature, and likelihood of pathogenic infection were significant factors related to plant death (Fig 4).

Soil temperature evaluation
Analysis of variance revealed only a significant soil temperature treatment effect in photochemical efficiency data. Therefore, data were pooled across experimental runs and ecotypes. Considering that ecotypes in this experiment were harvested from distinct microenvironments where we observed mortality or continued survival in our observational study, the lack of an ecotype effect in photochemical efficiency provides evidence that P. annua mortality is dictated by environmental conditions rather than programmed senescence common of annual plants.
Poa annua plants survived 28 days of exposure to soil temperatures of 21.1, 26.7, or 32.2˚C and senesced when subjected to 37.8˚C. Plants subjected to the 21.1˚C soil temperature remained healthy for the duration of the experiment as photochemical efficiency was near optimum (Fv/Fm of 0.79), ranging from 0.75 to 0.78 (Fig 5). Conversely, plants subjected to the 37.8˚C soil temperature exhibited drastically reduced photochemical efficiency from 7 DAT until the end of the study. Poa annua plants exposed to the 26.7 or 32.2˚C soil temperature treatments did not senesce but were negatively affected by prolonged exposure to elevated soil temperatures; both treatments numerically reduced photochemical efficiency from 21 to 42 days after treatment (DAT). For plants subjected to the 37.8˚C soil temperature,

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photochemical efficiency was drastically reduced from 0.71 at 7 DAT to 0.33 by 14 DAT, remaining � 0.02 thereafter, indicating death.
Only the 37.8˚C soil temperature treatment was lethal to P. annua plants with mortality first noted 12 DAT. By 17 DAT, 35 of 36 P. annua plants exposed to the 37.8˚C soil temperature had died. Reductions in P. annua plant health without death, except in extreme cases, when soil temperature is elevated supports other published reports [32,51]. For example, exposure of 115 P. annua selections to conditions of 47˚C at 100% relative humidity in a growth chamber for six hours did not cause mortality, however 77% of plants were negatively affected (< 50% recovery) [32]. Similarly, P. annua subjected to day/night air temperatures of 20/15, 30/25, or 40/35˚C for eight days in growth chambers resulted in physiological damage only from the supraoptimal temperature of 40/35˚C, although no plants senesced [51].
Survival of P. annua in these glasshouse experiments agreed with observations made in our life cycle monitoring experiment in the field. For example, peak soil temperature across all ten micro-environments was 30.8˚C (The Earthstream Platform; mesur.io, Yanceyville, NC) in 2020 and average daily air temperature did not exceed 28.7˚C. Given that some P. annua plants in the observational experiment senesced without soil temperatures exceeding 32.2˚C, we concluded that elevated soil temperature alone does not result in P. annua death.

Soil water evaluation
A log-rank test detected significant (P <0.0001) differences in survival probability among treatments. Survival probability for plants subjected to the well-watered + ambient soil temperature treatment was 100% throughout the experiment (Fig 6). No treatment resulted in a survival probability of 0% during the tested time frame. However, across all treatments, 27 of 72 tested P. annua plants did senesce. The lowest P. annua survival probability was observed for the full drought + elevated soil temperature treatment; Probability of survival was not reduced from 100% until 19 DAT and remained above 50% through 40 DAT. Comparatively, survival probability for plants exposed to the well-watered + elevated soil temperature and full drought + ambient temperature treatments was 100% through 34 DAT and remained above 70% through 42 DAT.
The ability of P. annua to survive an extended period with low water availability is documented [50]. These researchers did not observe P. annua senescence when plants were maintained in a sand-based medium with VWC from 4 to 12% for 95 days. While VWC treatments tested are similar to those achieved via drought stress treatment (6.6 to 8.4%) in this study, air and soil temperature were not published in their report [50]. Although a combination of full drought and elevated soil temperature was lethal to some P. annua plants in our experiment, it is telling that the probability of P. annua survival was still 25% after 42 days of continuous exposure to conditions that rarely occur in the field. Moreover, no other treatment combination in this experiment reduced the probability of P. annua survival to < 70% during the study. These responses indicate that interactions of soil moisture and temperature are not lethal to P. annua except in extreme situations atypical of managed urban grasslands.

Disease susceptibility evaluation
Poa annua plants in plots not treated with fungicide did not survive the summer period. High individual plant mortality was observed in non-treated areas on 24 June 2021 with some plots completely devoid of P. annua beginning on 8 July 2021 (Fig 7). By 4 August 2021, no P. annua plants were alive in any non-treated plots. Conversely, in plots treated with fungicide, some P. annua plants survived to the termination of the experiment.
The range of the anthracnose caused by C. cereale severity (Fig 7) in this experiment suggests that increases in zoysiagrass cover throughout the monitoring period (and a concomitant decline in P. annua plant size) may have affected our ability to document P. annua during summer. For example, zoysiagrass cover across the experimental area at study initiation was only 63%, whereas by 18 August 2021, zoysiagrass cover reached 88%. Zoysiagrass is a C 4 species adapted to the summer season in Knoxville, TN and P. annua is a C 3 species that is at a disadvantage during summer. Therefore, we surmised that zoysiagrass outcompeted P. annua for resources and caused a natural population dynamic shift. Inter-species competition with common bermudagrass (Cynodon dactylon Pers.) has limited P. annua persistence in summer months previously [8]. As zoysiagrass grew denser, P. annua became more difficult to assess via visual ratings. Without the presence of an inflorescence to clearly identify P. annua plants, it is possible plants were not identified, but persisted throughout the season (Fig 8). For example, fungicide treated plots scored as not containing P. annua on 4 August contained multi-tillered plants in autumn when temperatures cooled and suggest that the roots and underground shoots of the plants had survived the summer and grew rapidly when favorable environmental   conditions for growth were restored. This observation points to potential selection for ecotypes with an increased root to shoot ratio [67], which could support year-long survival via stress reduction or capitalization of resource acquisition compared with newly germinated seedlings.
Interestingly, several P. annua plants maintained vigorous growth throughout the experiment, producing inflorescences as early as 4 August 2021 (Fig 8). Poa annua emergence models developed in Knoxville, TN indicate peak emergence typically occurs between the 40 th and 43 rd week of the calendar year when mean seven-day soil temperature lowers to � 18.9ºC and seven-day rainfall accumulation is � 12.7 mm [68]. Observation of P. annua inflorescence production in only the 32 nd week of the year when soil temperatures were > 24 ºC and average weekly rainfall was < 4.75 mm (The Earthstream Platform; mesur.io, Yanceyville, NC) supports our assertion that observed plants were not newly germinated but had survived the summer season. Comparatively early inflorescence production aligns with findings of differing vernalization requirements and time to reproductive maturity among P. annua ecotypes [21,22,67].
Results of this experiment indicate that fungal pathogens are the primary cause of P. annua mortality in maintained urban grasslands. Although not all plants in fungicide treated plots survived or were observable, P. annua plants treated with fungicide lived markedly longer than those not treated with fungicide (Fig 7). F-score analysis of climatic data at the time of plant mortality revealed risk of anthracnose and brown patch infection as significant factors associated with mortality (Fig 9). On the first date mortality was documented in non-treated plots (24 June 2020), anthracnose acervuli were present on necrotic foliage.
Summer decline of P. annua via fungal infection is thoroughly discussed in pathology literature [52,58,69]. Fungicide use on P. annua managed as a desirable species is a readily accepted management practice for summer survival [70,71]. Some reports indicate P. annua cannot be commercially released until disease resistance is incorporated into the species because plants

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are so highly susceptible to pathogen attack [8]. Therefore, we recommend that susceptibility to fungal pathogens be considered when assessing the life cycle of P. annua.

Conclusions
Results of these experiments suggest P. annua perishes from fungal infection, which may be exacerbated by environmental and anthropogenic stresses during summer months [56,57,59]. Poa annua seems to persist unless environmental conditions are unfavorable, often presenting as a polycarpic plant rather than succumbing to programmed senescence. This environmentally driven response is similar to that of other perennial C 3 grass species such as Kentucky bluegrass (Poa pratensis L.) or tall fescue [Schedonorus arundinaceus (Schreb.) Dumort]. On the contrary, annual species are monocarpic plants senescing after a single reproductive cycle regardless of environment [3]. Our results show that P. annua does not meet the definition of an annual species. Observations made in this study and via an exhaustive review of peer-reviewed literature [60] present little evidence supporting an inherently annual life cycle in P. annua. We contend the epithet "annua" is a misnomer according to its current interpretation. Although "annual" can be associated with life cycle, "occurring once every year" is also a definition of the word [72]. Thus, the species epithet "annua" may have been awarded to P. annua to mark a yearly observation such as growth at the same location or yearly inflorescence production rather than of an annual life cycle.
Early taxonomic descriptions of P. annua provide no evidence of life cycle study at the time of naming, indicating the species name has been misconstrued in modern times [60]. The shift in present understanding of P. annua as a perennial rather than the long purported annual species has major implications for plant management. Therefore, a more appropriate and descriptive name may be P. typica or P. vulgari, meaning 'typical' and 'common' in Latin, respectively. These epithets preclude misinformation surrounding life cycle and indicate the species prevalence given that P. annua is found on all seven continents in a myriad of climates. August 2020 where A = a fine-texture, laterally growing plant with inflorescence in microenvironment two; B = a fine-texture, laterally growing plant in micro-environment six; C = an upright growing, coarse textured plant in micro-environment seven; and D = an upright growing, coarse textured plant in micro-environment nine. (TIF) S1